KR100702374B1 - Light source unit and display device - Google Patents

Abstract

(Problem) Provided are a light source device and a display device capable of effectively controlling a plurality of light sources emitting light of different wavelengths.

(Solution means) The light source device 100 includes a plurality of LED chips 106 and an optical sensor 201 that detects light from the mixed portion 104. The light source controller 202 controls the light emission intensity of each LED chip by feedback control in accordance with the detection value of the photosensor. The light source device includes a temperature control unit 207 for controlling the temperature of the light source 106. The temperature control unit is a feedback control system. By maintaining the temperature of the light source 106 at a predetermined value, it is possible to suppress the spectral shape change of the LED chip due to the temperature change, and as a result, it is easy to suppress the change in the luminance or chromaticity of the light source device.

Light source device, display device, light sensor, light source control unit, LED

Description

LIGHT SOURCE UNIT AND DISPLAY DEVICE}

1 is a cross-sectional view showing a schematic configuration of a liquid crystal display device according to a first embodiment.

2 is a block diagram showing a schematic configuration of a light source device according to the first embodiment.

3 is a diagram illustrating optical characteristics of the light source device according to the first embodiment.

4 is a block diagram showing a schematic configuration of a light source device according to a second embodiment.

5 is a block diagram showing a schematic configuration of a light source device according to a third embodiment.

Explanation of symbols on the main parts of the drawings

100: liquid crystal display module 101: backlight unit

102: liquid crystal display panel 103: optical sheet

104: Light guide plate 105: Reflective sheet

106: light source 107: lamp reflector

201: light sensor 202: light source control unit

203: setting unit 204: comparing unit

205: control unit 206: operation unit

207: temperature control 208: cooling and / or heater

209: controller 301,302,303 emission wavelength

304, 305, 306: detection wavelength of the optical sensor 401, 402: light source control unit

501: temperature control unit 502: controller

503: light source control unit 504: control unit

The present invention relates to a light source device and a display device, and more particularly, to a light source device and a display device capable of effectively controlling a plurality of light sources having different emission frequencies.

As image display devices for personal computers and other various monitors, liquid crystal display devices are spreading at an alarming speed. The liquid crystal display device typically has a liquid crystal display panel and a backlight unit arranged on the rear surface thereof. The liquid crystal display panel displays an image by controlling the transmitted light. The backlight unit typically includes a light source and a plurality of optical members for effectively emitting the light of the light source to the liquid crystal display panel. As a light source of a backlight unit, a cold cathode tube and a light emitting diode (LED) are known.

LEDs are increasingly used as a light source of a backlight unit because they have excellent color characteristics compared to cold cathode tubes. When using LED as a light source, some LED chips which emit a different color may be used. Typically, LED chips emitting three colors of red (R), green (G), and blue (B) are prepared, and light emission devices having desired emission colors are obtained by adjusting the emission intensity of each color. Can be. When used as a backlight unit of a liquid crystal display device, the light emission intensity of these LED chips is controlled so that white light is obtained. When using LEDs that emit light of different colors, it is necessary to mix the light from each LED in order to obtain the desired color of light.

The LED chip is a point light source, a directional light source, and several methods are known as a means for mixing light from the LED. One typical method uses a light guide plate. The light incident from the LED chips of each color into the light guide plate is diffused and propagates in the light guide plate so that the light of each color is mixed. LEDs have excellent color characteristics, but their light emitting characteristics are slightly unstable. In particular, the light emission characteristic of the LED is changed by a change in temperature or a change in temperature. Specifically, light emission luminance decreases due to changes over time. In addition, the emission intensity is changed by temperature change and the emission frequency is converted. Thus, the luminance or chromaticity of the light source device changes with time or temperature.

Since LED has such a characteristic, when using LED as a light source, it is required to detect the light from LED by an optical sensor and to control the light emission intensity of each LED chip. The condition required for such an optical sensor basically requires a visibility curve. However, the sensor of the visibility curve is difficult to manufacture and it is not easy to obtain an optical sensor having the required characteristics. On the other hand, an optical sensor having a band pass filter is known as a typical sensor whose detection sensitivity changes with frequency.

A sensor having a band pass filter can detect a change in luminance of a wavelength in a band, but cannot detect a change in spectral shape (color change) in a band correctly. This is because the band pass filter has a constant wavelength width, and the optical sensor detects the sum of the light of all wavelengths in the wavelength range and does not detect the light intensity for each wavelength in the band. As described above, the LED has a characteristic that a change in the spectral shape such as the emission wavelength is converted by the temperature change. The chromaticity change or luminance change as the light source device due to this wavelength conversion cannot be accurately detected by the optical sensor having a band pass filter.

By the way, the ultraviolet lamp is known as another light source whose light emission characteristic changes with temperature. Ultraviolet lamps are used, for example, as light sources in thermal printers. In a color thermal printer, a technique for improving printing characteristics by controlling temperature of an ultraviolet lamp is known (see Japanese Laid-Open Patent Publication No. 2000-301748). The ultraviolet lamp has a characteristic that the light emission amount is low when the tube wall temperature is low, and the light emission amount is increased as the tube wall temperature is increased, and is lowered when the temperature is higher. Therefore, it is necessary to keep the pipe wall temperature within a predetermined temperature range and keep the light quantity constant. By cooling the ultraviolet lamp, the cooling fan can maintain the tube wall temperature within a predetermined temperature range.

To control the cooling fan, a temperature sensor for measuring the tube wall temperature can be used. Alternatively, in order to more accurately detect the light emission characteristics of the ultraviolet lamp and to prevent the luminance gradient in the rod-shaped lamp, a plurality of illuminance sensors detect a light amount of the ultraviolet lamp and control the cooling fan by the detected amount. Known. The above technique can control a light source that emits a single light, but cannot effectively control a plurality of light sources that emit light of different wavelengths, such as a white light source device using an LED.

SUMMARY OF THE INVENTION The present invention has been made in view of the above prior art, and one object of the present invention is to provide a light source device and a display device capable of effectively controlling a plurality of light sources emitting light of different wavelengths.

A first light source device according to the present invention includes a plurality of light sources, a plurality of light sources each emitting light having a different wavelength, a temperature control unit operable to maintain temperatures of the plurality of light sources, and light from the plurality of light sources. A light mixing unit for mixing the light, a light detecting unit for detecting light from the light mixing unit, a light detecting unit capable of detecting light of a plurality of different wavelengths, and a plurality of light sources based on detection values of the light detecting unit. The light source control part which controls the light intensity of this is provided. By providing this structure, the some light source which emits light of a different wavelength can be effectively controlled.

In the first light source device, the light detector detects light of a plurality of different wavelength bands, and the light source controller is configured to detect light of the plurality of light sources such that each of the detected values in the plurality of wavelength bands approaches a predetermined value. The intensity can be controlled. By providing this configuration, it is possible to suppress the change in the spectral shape in the detection wavelength range and to effectively control the plurality of light sources.

The first light source device may further include a temperature detector that detects a temperature of the plurality of light sources, and the temperature controller may operate such that a detected value of the detector is close to a predetermined value. By providing this structure, the spectral shape change of a light source can be suppressed.

In the first light source device, the temperature control unit operates to maintain the plurality of light sources at a predetermined temperature, and the light source control unit controls the light intensity of the plurality of light sources so that the chromaticity of the light of the light source device is substantially constant. can do. By providing this structure, the spectral shape change of a light source can be suppressed and the chromaticity change of the light of a light source device can be suppressed effectively.

The first light source device further includes a temperature detector that detects temperatures for the plurality of light sources, wherein the temperature controller is capable of varying the temperature held based on the temperature detected by the temperature detector, The light source controller may control each of the plurality of light sources to emit light at a light intensity set corresponding to the maintained temperature. By providing this structure, a light source can be effectively controlled corresponding to the spectral shape change by the temperature change of a light source.

A second light source device according to the present invention is a plurality of light sources, each of which includes a plurality of light sources emitting light of different wavelengths, a light mixing portion for mixing light from the plurality of light sources, and light from the light mixing portion. A light detecting unit for detecting a light source, the light detecting unit capable of detecting light having a plurality of different wavelengths, a temperature detecting unit detecting a temperature of the light source, a detected value of the light detecting unit, and a detected value of the temperature detecting unit. And a light source controller for controlling the intensity of light from the plurality of light sources. By providing this structure, the some light source which emits light of a different wavelength can be effectively controlled.

In the second light source device, the light source controller may change the light emission intensity of the plurality of light sources so as to suppress a change in chromaticity of light from the light source device based on a change in the detection value of the temperature detector. By providing this structure, a light source can be effectively controlled corresponding to the spectral shape change by the temperature change of a light source.

In the first or second light source device, the plurality of light sources are constituted by a light source that emits light of a wavelength corresponding to each of N (N is a natural number) color, and the light detector is configured to respectively light the N color. N light sensors corresponding to the light source controller may control the plurality of light sources such that each of the detected values of the N light sensors approaches a predetermined value. By providing this structure, a light source can be controlled more correctly.

In the second light source device, the light source controller may control each of the plurality of light sources to emit light at an emission intensity set corresponding to the temperature detected by the temperature detector. By providing this structure, a light source can be effectively controlled corresponding to the spectral shape change by the temperature change of a light source.

A first display device of the present invention is a display device having a light source device and a display panel for displaying by controlling light from the light source device, wherein the light source device is a plurality of light sources, each emitting light having a different wavelength. A plurality of light sources, a temperature control unit operable to maintain the temperatures of the plurality of light sources, a light mixing unit for mixing light from the plurality of light sources, and a light detection unit for detecting light from the light mixing unit, And a light detector that can detect light of a plurality of different wavelengths, and a light source controller that controls the light intensities of the plurality of light sources based on the detected values of the light detectors. By providing this structure, a light source can be effectively controlled corresponding to the spectral shape change by the temperature change of a light source.

A second display device of the present invention is a display device comprising a light source device and a display panel for displaying by controlling light from the light source device, wherein the light source device is a plurality of light sources, each emitting light having a different wavelength. A plurality of light sources to be mixed, a light mixing unit to mix light from the plurality of light sources, a light detecting unit to detect light from the light mixing unit, and a light detecting unit capable of detecting light of a plurality of different wavelengths; And a light source controller for detecting a temperature of the light source, and a light source controller for controlling the intensity of light from the plurality of light sources based on the detected value of the light detector and the detected value of the temperature detector. By providing this structure, a light source can be effectively controlled corresponding to the spectral shape change by the temperature change of a light source.

[Embodiment of the Invention]

Embodiments to which the present invention can be applied are described below. The following description describes embodiments of the present invention, and the scope of the present invention is not limited to the following embodiments. Those skilled in the art can implement necessary or possible changes, conversions, additions or omissions in the following embodiments within the scope of the present invention. In addition, the following description is suitably simplified or modified in an actual structure and dimension for clarity of description.

Embodiment 1

This embodiment controls the temperature of the light source having a plurality of different wavelengths. By maintaining the temperature of the light source, it is possible to effectively control the brightness and chromaticity of the light emitted from the light source.

1 is a cross-sectional view for explaining the overall configuration of a liquid crystal module in the present embodiment. 1 shows an outline of a liquid crystal module 100 having a side light type backlight unit. In FIG. 1, 101 is a backlight unit, and 102 is a liquid crystal display panel equipped with a driving circuit (not shown). 103 is an optical sheet, and a prism sheet for improving the brightness of the front of the display by condensing light, and a diffusion sheet for uniforming the brightness of the display surface by diffusing transmitted light are disposed. 104 is a light guide plate for guiding and diffusing light from a light source, and 105 is a reflection sheet for reflecting incident light.

106 is a plurality of light sources emitting light of different wavelengths (colors), and typically a light emitting diode (LED) is used. The light source 106 is not limited to the LED, and various light sources emitting light of different wavelengths can be used. For example, organic EL (Electro Luminescence), inorganic EL, etc. can be used. 107 is a lamp reflector that surrounds the light source 106 and reflects the light. The liquid crystal display panel 102 and the other optical members are accommodated in a frame and supported and protected from the outside by a bezel disposed on the upper surface of the display panel. The backlight unit 101 includes an optical sheet 103, a light guide plate 104, a reflective sheet 105, and a light source 106.

The liquid crystal display panel 102 includes a display area composed of a plurality of pixels arranged in a matrix and an edge area that is an outer peripheral area thereof. In addition, the liquid crystal display panel 102 includes an array substrate on which an array circuit is formed and an opposing substrate, and a liquid crystal is enclosed between the two substrates. The color liquid crystal display device has a color filter layer of RGB on the opposing substrate. Each pixel in the display area of the liquid crystal display panel 102 displays any one color of RGB. Of course, the monochrome display displays either black or white. In the display area on the array substrate, a plurality of signal lines and gate lines are arranged in a matrix. The signal lines and the gate lines overlap each other at right angles.

Each pixel selected by the gate voltage input from the gate driver IC (not shown) applies an electric field to the liquid crystal based on the display signal voltage input from the source driver IC. The voltage input from the source driver IC is sent to the pixel electrode through the source / drain of the TFT, and the pixel electrode and the common electrode apply an electric field to the liquid crystal. By changing this voltage, the voltage applied to the liquid crystal can be changed, and the light transmittance of the liquid crystal is controlled. The circuit for applying a common potential to the common electrode is configured on a control circuit board (not shown). In addition to the active matrix type, a liquid crystal display panel is known as a simple matrix type having no switching element. The present invention can be applied to various types of liquid crystal display panels. Alternatively, the present invention can be applied to various display devices that control light from the planar light source device by the display panel.

The optical operation of the backlight unit will be described. Light emitted from the light source 106 is directly or reflected by the lamp reflector 107 and is incident into the light guide plate 104. Light of different wavelengths incident into the light guide plate is diffused and mixed by propagating in the light guide plate. The mixed light exits from the light exit surface 104a (the upper surface of the light guide plate in the drawing) of the light guide plate and is incident on the liquid crystal display panel 102 through the optical sheet 103. In this embodiment, although the light guide plate 104 is used as a means for mixing the light from the light source 106, light of different wavelengths can be mixed using another optical member or an air layer instead of the light guide plate.

2 is a plan view for explaining a schematic configuration of a side light type backlight unit which is a light source device according to the present embodiment. In FIG. 2, the same reference numerals as those used in FIG. 1 denote the same elements, and thus descriptions thereof will be omitted. In FIG. 2, 201 is an optical sensor for detecting light from the light guide plate 104. 202 is a light source controller for controlling the light source. The light source control unit 202 is a feedback control system, and includes a setting unit 203, a comparison unit 204, an adjustment unit 205, and an operation unit 206. 207 is a temperature controller for controlling the temperature of the light source. The temperature control unit 207 includes a cooling and / or heater 208 that functions to maintain the temperature of the light source 106, and a controller 209 that controls the cooling and / or heater 208.

In this embodiment, an example of using LED as a light source is described. The backlight unit 101 is provided as a light source 106 with a plurality of LED chips emitting light of different wavelengths. Typically, three types of LED chips of red (R), green (G), and blue (B) are mounted. For each color LED chip, an appropriate number or arrangement is selected so that light having the required chromaticity and luminance is emitted from the light source device. The type of LED to be mounted is not limited to three colors of RGB, and a plurality of types of LED chips of different colors can be used.

Moreover, it is not limited to the LED chip which emits light of three different wavelengths, LED chip which emits light of two types or four or more different wavelengths can be used. In light of being able to emit light having many chromaticities, the light source device preferably has a light source of three or more colors. Moreover, it is preferable to have a light source of three colors from a viewpoint of controllability and a part score. It is preferable to have a light source of three colors which can form white light as a light source device of a display apparatus.

The optical sensor 201 detects light emitted from the light guide plate 104 which is a light mixing portion. Preferably, the photosensor 201 detects the light emitted from the side of the light guide plate. The optical sensor 201 can detect light of a plurality of different wavelengths. The backlight unit 101 may be provided with a plurality of optical sensors capable of detecting light of different wavelengths. Each sensor can detect the intensity of light in a wavelength range having a predetermined bandwidth, and is selected so that each wavelength range is different. Each wavelength of the light source 106 is included in the detection wavelength range of the at least one optical sensor. Each wavelength range of the optical sensor includes at least one wavelength of the light source. Typically, the number of light source types and the number of light sensor types are the same. For example, three kinds of optical sensors having a band pass filter corresponding to three colors can be prepared for a light source having three colors of LEDs. The number of photosensors may also be more or less than the number of different frequencies that the light sources 106 emit as long as the brightness and chromaticity of the light sources can be controlled. By providing another optical sensor and using an optical sensor by time division, the light intensity of several different wavelength can be detected.

The light source control unit 202 controls the light emission intensity of each light source included in the light source 106 by feedback control based on the detection value detected by the photosensor 201. The light emission intensity of each light source is controlled so that the detected value of the photosensor approaches the predetermined value. The predetermined value may be, for example, a specific area having a specific value or width. Control is performed so that the brightness and chromaticity of the light from the backlight unit are maintained. The setting unit 203 determines a reference value for feedback control. The reference value can be stored in advance. The comparison unit 204 compares the value detected by the optical sensor 201 with the reference value acquired from the setting unit 203 and outputs the difference. The adjusting unit 205 determines the amount of operation to be fed back to the light source based on the comparison result and the feedback coefficient of the comparing unit 204. The feedback coefficient can be stored in advance. The operation unit 206 operates the LED chip based on the output of the adjustment unit 205. The light source control unit 202 can be realized using a microcomputer and software or by a hardware configuration.

An operation example of the light source control unit 202 will be described. In the following description, for the sake of clarity, an example composed of three optical sensors having a band pass filter corresponding to each of three colors of RGB as the optical sensor 201 is shown. Each of the detected values detected by each optical sensor is input to the light source control unit 202. The detected value is used as a value for which conversion necessary for data processing has been performed. The comparison unit 204 determines the difference between the detected value of each sensor and the reference value corresponding to each sensor acquired from the setting unit 203, and outputs the difference to the adjustment unit 205. The adjusting unit 205 is provided with a feedback coefficient for correlating the difference between the detection value and the reference value of each sensor and the amount of feedback to each LED chip. The adjusting unit 205 determines the amount of operation to be fed back so that the detected value of each sensor approaches the reference value from the difference between the detected value of each sensor acquired from the comparing unit 204 and the reference value. The operation unit 206 operates the light emission luminance of each LED chip in accordance with the feedback amount obtained from the adjustment unit.

3 is a diagram showing an example of the relationship between the detection wavelength range of the optical sensor 201 and the wavelength of light emitted from the light source. For clarity, an optical sensor with a steep band pass filter corresponding to each color of RGB is shown. 3 shows an example, and the wavelength of the light from the optical sensor and the light source of the present invention is not limited to the relationship shown. In FIG. 3, the X axis represents the wavelength of light and the Y axis represents relative intensity. Each of 301, 302, and 303 represents the wavelength and intensity of light emitted from different LED chips. Each of 304, 305, and 306 has shown the relationship between the wavelength range of the light which the optical sensor 201 detects, and detection sensitivity. The LED has a characteristic that not only the luminance but also the emission wavelength changes with the change of temperature.

Hereinafter, the relationship between the light emission characteristics of the LED and the photosensor according to temperature will be described with a simple example. The LED chip that emits light having a wavelength of 303 emits light of 303a at a predetermined temperature, but emits light having a wavelength indicated by 303b when the temperature is changed. The optical sensor 201 detects the light 303 from the light source within the detection wavelength region indicated by 306. In the example of FIG. 3, the optical sensor 201 can detect a change in intensity of the light 303, but cannot detect wavelength conversion from 303a to 303b, and if 303a and 303b are the same intensity, they detect the same value. do. Therefore, even if the chromaticity of the light source device is changed by the wavelength conversion, the change cannot be accurately detected. As described above, when the sensor is out of the visibility, such as an optical sensor having a band pass filter, if the spectral shape of the light source is changed, there is a deviation between the detection of the light with the visibility and the detection with the sensor.

The light source device of this embodiment has a temperature controller 207 for controlling the temperature of the light source 106. The temperature control unit 207 is a feedback control system. By maintaining the temperature of the light source 106 at a predetermined value, it is possible to suppress the spectral shape change of the LED chip due to the temperature change, and as a result, it is easy to suppress the change in the luminance or chromaticity of the light source device. The predetermined value can be, for example, a specific temperature or a specific temperature range. The temperature control unit 207 controls the temperature of the light source based on the detected value of the temperature sensor 210. The temperature sensor 210 can use a thermocouple, a thermistor, etc., for example. The temperature sensor 210 has an appropriate number of sensors disposed at appropriate positions so that the temperature can be effectively detected with respect to the light source.

The temperature control unit 207 can cool and / or heat the light source 106 by the cooling and / or heater 208. As the cooling and / or heater 208, a cooling fan, an electric heater, a Peltier element or the like can be used. Cooling and / or heater 208 may have only a cooler or heater as needed. In addition, the cooling and / or heaters 208 are disposed at appropriate numbers and in appropriate positions so that the temperatures of the plurality of light sources can be effectively controlled.

The temperature detection value detected by the temperature sensor 210 is input to the controller 209. The controller 209 can memorize a preset set temperature or set temperature range. The controller 209 controls the cooling and / or heater 208 based on the temperature detection value and the set value detected by the temperature sensor 210. The controller 209 can control the temperature detection zone to be close to or within a predetermined range.

This embodiment suppresses the spectral shape change of an LED chip by controlling the temperature of an LED chip. As a result, the luminance and chromaticity of the light source device can be effectively kept constant.

Embodiment 2

4 is a diagram illustrating a schematic configuration of a light source device of this embodiment. In FIG. 4, the same coded elements as those in FIG. 2 correspond to the same elements as those in FIG. The light source device 101 of this embodiment does not have the temperature control part 207 in FIG. In FIG. 4, 401 is an adjusting unit that determines an operation amount of the light source 106 based on the detected value of the temperature sensor 210. 402 is a light source control unit including an adjusting unit 401. The adjusting unit 401 may store a plurality of different feedback coefficients in advance, or calculate different feedback coefficients corresponding to the temperature. Each feedback coefficient is associated with each of a plurality of different temperatures or temperature ranges. The light source device is controlled to suppress the chromaticity change of the light source device due to the temperature change by feedback control based on the temperatures of the plurality of light sources.

Each feedback coefficient associated with the temperature is determined based on the spectral sensitivity characteristics of the photosensor and the spectral shape change of the LED chip according to the temperature change, and is set so that the emitted light chromaticity of the light source device at each temperature becomes substantially constant. The adjusting unit 401 may have a table in which feedback coefficients and detection values are associated. The table may correspond to a predetermined temperature or temperature range and the feedback coefficient. The table can be formed by using the measured values or linear interpolation between the measured values. The adjusting unit 401 can also determine the feedback coefficient for the temperature not stored in the table, for example, by linear interpolation.

The temperature sensor 210 detects a temperature relating to the light source 106 and outputs the detected value. The adjusting unit 401 acquires the detected value detected by the temperature sensor 210 and determines the feedback coefficient based on the value and the table. The adjusting unit 401 determines the operation amount based on the value obtained from the comparing unit 204 and the feedback coefficient determined based on the temperature of the light source. The manipulated variable is output to the operation unit 206. The operation unit 206 controls the light emission intensity of each LED chip based on the acquired operation amount. Since each LED chip is controlled to emit light at a set emission intensity corresponding to the value detected by the temperature sensor, it is possible to effectively suppress the change in chromaticity of the light source device due to the temperature change.

In this embodiment, since the operation amount of the light source is controlled based on the temperature of the light source, even if the spectral shape change of the LED chip occurs due to the temperature change, the emitted light chromaticity of the light source device can be maintained substantially constant.

In addition, instead of the adjusting unit 401, the setting unit 203 outputs different setting values based on the temperature, thereby suppressing the chromaticity change caused by the temperature change. The setting unit 203 may store a plurality of different reference values in advance or calculate different reference values corresponding to the temperature. Each reference value is associated with each of a plurality of different temperatures or temperature ranges. The setting unit 203 acquires the detection value detected by the temperature sensor 210 and determines the reference value based on the value. The setting unit 203 can output a reference value based on the temperature of the light source by providing a table, for example, like the adjustment unit 401. Moreover, a temperature control part can be added to the light source device of this form. By changing the light emission intensity of the plurality of light sources based on the temperature change of the plurality of light sources, it is possible to effectively maintain the emission chromaticity of the light source device even if the spectral shape change of the light source occurs due to the temperature change.

Embodiment 3

5 is a diagram illustrating a schematic configuration of a light source device of this embodiment. In FIG. 5, the same reference numerals as those in FIG. 2 correspond to the same elements as those in FIG. In FIG. 5, 501 is a temperature controller, which can control the light source 106 with respect to a plurality of different temperatures. The temperature control unit 501 includes a cooling and / or heater 208 and a controller 502. The cooling and / or heater 208 has the same configuration as the first embodiment. The controller 502 can change the set temperature for holding the light source. For example, controller 502 can control cooling and / or heater 208 to bring light source 106 close to a plurality of different specific temperatures or specific temperature ranges.

For example, if the external temperature rises and the light source 106 cannot be maintained at the first temperature, the controller 502 may cool and / or the heater 208 to maintain the light source 106 at a second temperature higher than the first temperature. To control. The controller 502 can previously store a plurality of controllable specific temperatures or specific temperature regions of the light source 106. The controller 502 can have a table that correlates the temperature detected by the temperature sensor 210 with the controllable temperature. The set temperature can be a temperature range having a specific temperature or width.

503 is a light source control unit, and 504 is an adjusting unit for determining an operation amount of the light source 106 based on the set temperature of the controller 502. The adjusting unit 504 may store a plurality of different feedback coefficients in advance, or calculate different feedback coefficients corresponding to the temperature. Each feedback coefficient is associated with each of the set temperature or temperature range of the controller 502. Each feedback coefficient is determined based on the spectral change of the LED chip according to the temperature change, and is set so that the emitted light chromaticity of the light source device at each temperature becomes substantially constant. The adjusting unit 504 may have a table in which a feedback coefficient and a setting value of the controller are associated with each other. The table can be formed by using the measured values or linear interpolation between the measured values.

The temperature sensor 210 detects a temperature relating to the light source 106 and outputs the detected value. The controller 502 can determine the set temperature or the set temperature range corresponding to the detected value by acquiring the detected value of the temperature sensor 210 and referring to the preset table. The controller 502 controls the cooling and / or heater 208 such that the detected value of the temperature sensor is close to, or within, the set temperature range. The controller 502 also outputs the set temperature toward the adjusting unit 504. The adjusting unit 504 obtains the set temperature from the controller 502 and determines the feedback coefficient based on the set temperature. The feedback coefficient may be determined by referring to a preset table. The table has feedback coefficients associated with each set temperature or set temperature range. The feedback coefficient is set so that the light chromaticity of the light source device at each temperature becomes constant.

In addition, the adjusting unit 504 may determine the feedback coefficient based on the detection value detected by the temperature sensor instead of the set temperature determined by the controller. In response to the detected value detected by the temperature sensor, a plurality of feedback coefficients are set in the adjusting unit.

In addition, instead of the adjusting unit 504, the setting unit 203 can output different setting values based on the set temperature of the controller. As a result, chromaticity change due to temperature change can be suppressed. The setting unit 203 may store a plurality of different reference values in advance or calculate different reference values corresponding to the set temperatures. Each reference value is associated with each of the set temperature or set temperature range that the controller 502 outputs. The setting unit 203 acquires a setting value set by the controller 502 and determines a reference value based on the value. The setting unit 203 can output a reference value based on the temperature of the light source, for example, by providing a table.

As described above, in the present embodiment, the plurality of light sources are controlled to emit light by changing the predetermined values held with respect to the temperatures of the plurality of light sources and by the light emission intensity corresponding to the predetermined values. Thus, the temperature can be effectively controlled, and the light chromaticity of the light source can be effectively kept constant.

The present invention is not limited to the form described above, and can be applied to various light source devices. For example, the present invention can be applied to a light source device having a light guide plate for emitting light to a display panel and a light guide plate as a light mixing unit for mixing light from a plurality of LEDs. In addition, the present invention can be applied not only to the light source device of the display device but also to light source devices of various uses.

The present invention can provide a light source device and a display device capable of effectively controlling a plurality of light sources emitting light of different wavelengths.

Claims (11)

A plurality of light sources each emitting light of a different wavelength; A temperature controller operative to maintain temperatures of the plurality of light sources; A light mixing unit for mixing light from the plurality of light sources; A light detection unit that detects light from the light mixing unit and detects light of the plurality of different wavelengths; And And a light source controller for controlling the light intensities of the plurality of light sources based on the detected values of the light detectors. The method of claim 1, The light detector detects light of a plurality of different wavelength ranges, And the light source control unit controls the light intensities of the plurality of light sources such that each of the detection values in the plurality of wavelength ranges approaches a respective reference value. The method of claim 1, Further comprising a temperature detector for detecting the temperature of the plurality of light sources, And the temperature control unit operates so that the detected value of the temperature detection unit approaches a reference temperature. The method of claim 1, The temperature control unit operates to maintain the plurality of light sources at a reference temperature, The light source controller controls the light intensity of the plurality of light sources so that the chromaticity of the light of the light source device is constant. The method of claim 1, Further comprising a temperature detector for detecting the temperature of the plurality of light sources, The temperature control unit may change the temperature maintained based on the temperature detected by the temperature detection unit, And the light source controller controls each of the plurality of light sources to emit light at a light intensity set corresponding to the maintained temperature. A plurality of light sources each emitting light of a different wavelength; A light mixing unit for mixing light from the plurality of light sources; A light detector which detects light of a plurality of different wavelengths and detects light from the light mixing unit; A temperature detector detecting a temperature of the light source; And And a light source controller for controlling the intensity of light from the plurality of light sources based on the detected value of the light detector and the detected value of the temperature detector. The method of claim 6, And the light source control unit changes the light emission intensity of the plurality of light sources so as to suppress a change in chromaticity of light from the light source device based on a change in the detected value of the temperature detector. The method according to claim 1 or 6, The plurality of light sources are constituted by a light source that emits light of a wavelength corresponding to each of N (N is a natural number) color, The light detector includes N light sensors corresponding to each of the N colored lights, And the light source control unit controls the plurality of light sources such that each of the detected values of the N photosensors approaches a respective reference value. The method of claim 6, And the light source control unit controls each of the plurality of light sources to emit light at an emission intensity set corresponding to the temperature detected by the temperature detector. A display device comprising a light source device and a display panel that displays by controlling light from the light source device. The light source device, A plurality of light sources each emitting light of a different wavelength; A temperature controller operative to maintain temperatures of the plurality of light sources; A light mixing unit for mixing light from the plurality of light sources; A light detector which detects light of a plurality of different wavelengths and detects light from the light mixing unit; And And a light source controller for controlling the light intensities of the plurality of light sources based on the detected values of the light detectors. A display device comprising a light source device and a display panel that displays by controlling light from the light source device. The light source device, A plurality of light sources each emitting light of a different wavelength; A light mixing unit for mixing light from the plurality of light sources; A light detector which detects light of a plurality of different wavelengths and detects light from the light mixing unit; A temperature detector detecting a temperature of the light source; And And a light source controller for controlling the intensity of light from the plurality of light sources based on the detected value of the light detector and the detected value of the temperature detector.

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